Gene structure in the tryptophan operon of Escherichia coli: Nucleotide sequence of trpC and the flanking intercistronic regions

We have determined the DNA sequence for the portion of the Escherichia coli tryptophan (trp) operon spanning trpC, which codes for the bifunctional enzyme N-(5′-phosphoribosyl)-anthranilic acid isomerase/indole-3-glycerol phosphate synthetase. The coding region consists of 1356 nucleotides, directing the synthesis of a polypeptide 452 amino acids in length. The predicted protein sequence is consistent with the amino acid composition of the pure enzyme, and with all known partial peptide sequences derived from this molecule. The enzyme is of particular functional interest, because it contains the catalytic activities for two sequential reactions in tryptophan biosynthesis in a single polypeptide chain.The nucleotide sequences of the junctions between trpC and its flanking genes, trpD and trpB, have also been determined. The trpD-trpC junction consists of six untranslated nucleotides and translation of trpC initiates at the second of two adjacent AUG codons. The trpC termination codon is separated from trpB by 11 nucleotides. The short non-translated regions flanking trpC distinguish it from trpA and trpD, whose initiation codons overlap the termination codons of the preceding genes (trpB and trpE), respectively. These differences in the intercistronic regions may reflect functional relationships between the products of adjacent genes in the operon.     

Nucleotide sequence of the trpB gene in Escherichia coli and Salmonella typhimurium

We have obtained the entire nucleotide sequence of the penultimate gene of the tryptophan operon, trpB, in Escherichia coli and Salmonella typhimurium. The amino acid sequence deduced for the E. coli gene product is in agreement with earlier, fragmentary protein sequence results. The trpB nucleotide sequences for the two bacterial species are perfectly colinear and show 85% identity. Most of the nucleotide differences found are without consequence for the amino acid sequence, which shows greater than 96% identity. The degree of conservation of both the nucleotide and amino acid sequences is significantly greater than for trpA, the adjacent gene encoding the other subunit of the same enzyme. When synonymous third codon position nucleotide differences are examined, they seem to be distributed at random throughout trpB and trpA, except for one completely conserved 66 basepair long region within trpB.     

An archaebacteria-derived glutamyl-tRNA synthetase and tRNA pair for unnatural amino acid mutagenesis of proteins in Escherichia coli

The addition of novel amino acids to the genetic code of Escherichia coli involves the generation of an aminoacyl-tRNA synthetase and tRNA pair that is ‘orthogonal’, meaning that it functions independently of the synthetases and tRNAs endogenous to E.coli. The amino acid specificity of the orthogonal synthetase is then modified to charge the corresponding orthogonal tRNA with an unnatural amino acid that is subsequently incorporated into a polypeptide in response to a nonsense or missense codon. Here we report the development of an orthogonal glutamic acid synthetase and tRNA pair. The tRNA is derived from the consensus sequence obtained from a multiple sequence alignment of archaeal tRNA^Glu sequences. The glutamyl-tRNA synthetase is from the achaebacterium Pyrococcus horikoshii. The new orthogonal pair suppresses amber nonsense codons with an efficiency roughly comparable to that of the orthogonal tyrosine pair derived from Methanococcus jannaschii, which has been used to selectively incorporate a variety of unnatural amino acids into proteins in E.coli. Development of the glutamic acid orthogonal pair increases the potential diversity of unnatural amino acid structures that may be incorporated into proteins in E.coli.     

Nucleotide sequence of Escherichia coli pyrG encoding CTP synthetase

The amino acid sequence of Escherichia coli CTP synthetase was derived from the nucleotide sequence of pyrG. The derived amino acid sequence, confirmed at the N terminus by protein sequencing, predicts a subunit of 544 amino acids having a calculated Mr of 60,300 after removal of the initiator methionine. A glutamine amide transfer domain was identified which extends from approximately amino acid residue 300 to the C terminus of the molecule. The CTP synthetase glutamine amide transfer domain contains three conserved regions similar to those in GMP synthetase, anthranilate synthase, p-aminobenzoate synthase, and carbamoyl-P synthetase. The CTP synthetase structure supports a model for gene fusion of a trpG-related glutamine amide transfer domain to a primitive NH3-dependent CTP synthetase. The major 5' end of pyrG mRNA was localized to a position approximately 48 base pairs upstream of the translation initiation codon. Translation of the gene eno, encoding enolase, is initiated 89 base pairs downstream of pyrG. The pyrG-eno junction is characterized by multiple mRNA species which are ascribed to monocistronic pyrG and/or eno mRNAs and a pyrG eno polycistronic mRNA.     

The regulation of tryptophan biosynthesis in Pseudomonas aeruginosa

Summary Eighteen auxotrophs of Pseudomonas aeruginosa requiring l-tryptophan for growth were isolated following nitrosoguanidine mutagenesis. Mutant blocks for each step of tryptophan biosynthesis were identified by enzymological assay. A regulatory mutant was characterized which was simultaneously constitutive for the gene products of trpA, trpB and trpD. Another class of regulatory mutant appears to synthesize tryptophan synthetase (i.e., trpE and trpF subunits) constitutively. The results implicate three control entities in the pathway of tryptophan biosynthesis: (i) The gene products of trpA, trpB and trpD are repressible by tryptophan, the range of enzyme specific activity varying at least fifty-fold. (ii) No regulation of the trpC gene product could be demonstrated, indicating that its synthesis is constitutive. (iii) The gene products of rpE and trpF are inducible by indoleglycerol 3-phosphate; the magnitude of induction can exceed 100-fold. These results together with some genetic data indicate a general similarity in gene-enzyme relationships between P. aeruginosa and P. putida. A number of specific differences that distinguish the two species are noted.A mutant blocked in the common pathway of aromatic biosynthesis was used to prove that enzymes of tryptophan biosynthesis other than tryptophan synthetase are not inducible by precursors of the common pathway such as chorismate. It is concluded that the concentration of tryptophan that signals total repression of the gene products of trpA, trpB and trpD is lower than the concentrations necessary for maximal feedback inhibition of anthranilate synthetase and for abolition of the induction of tryptophan synthetase.     

Cloning, analysis, and bacterial expression of human farnesyl pyrophosphate synthetase and its regulation in Hep G2 cells

A partial length cDNA encoding farnesyl pyrophosphate synthetase (hpt807) has been isolated from a human fetal liver cDNA library in lambda gt11. DNA sequence analysis reveals hpt807 is 1115 bp in length and contains an open reading frame coding for 346 amino acids before reaching a stop codon, a polyadenylation addition sequence, and the first 14 residues of a poly(A+) tail. Considerable nucleotide and deduced amino acid sequence homology is observed between hpt807 and previously isolated rat liver cDNAs for farnesyl pyrophosphate synthetase. Comparison with rat cDNAs suggests that hpt807 is about 20 bp short of encoding the initiator methionine of farnesyl pyrophosphate synthetase. The human cDNA was cloned into a prokaryotic expression vector and Escherichia coli strain DH5 alpha F'IQ was transformed. Clones were isolated that express an active fusion protein which can be readily observed on protein gels and specifically stained on immunoblots with an antibody raised against purified chicken farnesyl pyrophosphate phosphate synthetase. These data confirm the identity of hpt807 as encoding farnesyl pyrophosphate synthetase. Slot blot analyses of RNA isolated from Hep G2 cells show that the expression of farnesyl pyrophosphate synthetase mRNA is regulated. Lovastatin increases mRNA levels for farnesyl pyrophosphate synthetase 2.5-fold while mevalonic acid, low-density lipoprotein, and 25-hydroxycholesterol decrease mRNA levels to 40-50% of control values.     

Evolution of the genetic code.

Comparative path lengths in amino acid biosynthesis and other molecular indicators of the timing of codon assignment were examined to reconstruct the main stages of code evolution. The codon tree obtained was rooted in the 4 N-fixing amino acids (Asp, Glu, Asn, Gln) and 16 triplets of the NAN set. This small, locally phased (commaless) code evidently arose from ambiguous translation on a poly(A) collector strand, in a surface reaction network. Copolymerisation of these amino acids yields polyanionic peptide chains, which could anchor uncharged amide residues to a positively charged mineral surface. From RNA virus structure and replication in vitro, the first genes seemed to be RNA segments spliced into tRNA. Expansion of the code reduced the risk of mutation to an unreadable codon. This step was conditional on initiation at the 5'-codon of a translated sequence. Incorporation of increasingly hydrophobic amino acids accompanied expansion. As codons of the NUN set were assigned most slowly, they received the most nonpolar amino acids. The origin of ferredoxin and Gln synthetase was traced to mid-expansion phase. Surface metabolism ceased by the end of code expansion, as cells bounded by a proteo-phospholipid membrane, with a protoATPase, had emerged. Incorporation of positively charged and aromatic amino acids followed. They entered the post-expansion code by codon capture. Synthesis of efficient enzymes with acid-base catalysis was then possible. Both types of aminoacyl-tRNA synthetases were attributed to this stage. tRNA sequence diversity and error rates in RNA replication indicate the code evolved within 20 million yr in the preIsuan era. These findings on the genetic code provide empirical evidence, from a contemporaneous source, that a surface reaction network, centred on C-fixing autocatalytic cycles, rapidly led to cellular life on Earth.     

Actin genes and actin messenger RNA in Acanthamoeba castellanii. Nucleotide sequence of the split actin gene I

From Acanthamoeba castellanii we have isolated and completely sequenced an actin gene which is interrupted by a 129 base-pair intervening sequence following the codon for amino acid 105. S₁ nuclease mapping experiments indicated that this gene (actin gene I) is expressed in vivo. There is only one size class (1300 nucleotides) of actin messenger RNA in Acanthamoeba. We have used specific fragments of the isolated gene to demonstrate that there are at least three and possibly more actin genes in this organism. As deduced from the DNA structure, the Acanthamoeba actin I is a protein of 374 amino acids and has an unusual glycine residue at its N-terminus.     

Cloning and Sequence Analysis of a cDNA from Seminal Vesicle Tissue Encoding the Precursor of the Major Protein of Bull Semen

Abstract

A cDNA library derived from poly(A)⁺RNA of bull seminal vesicle- tissue was screened with a synthetic DNA hybridisation probe specific for the major protein of bull semen. A positive clone pMP17, containing a 680 bp insert, was sequenced. In combination with primer extension sequencing of poly(A)⁺RNA, a DNA sequence of 700 bp was determined. This DNA encoded a reading frame for 134 amino acids, starting with an ATG and terminated by a TAG codon. This comprised 25 amino acids of a signal peptide followed by 109 amino acids with the known sequence of the major protein.     

In vitro, the major ribosome binding site on Rous sarcoma virus RNA does not contain the nucleotide sequence coding for the N-terminal amino acids of the gag gene product.

Ribosomes from the reticulocyte lysate bind strongly and mainly to a region located in the 5' end of the Rous sarcoma virus RNA molecule between residues 9 and 53. This binding involves the participation of initiator tRNA and is sensitive to inhibitors of initiation of protein synthesis such as 7-methyl-GMP and aurintricarboxylic acid. The nucleotide sequence of this ribosome binding site has been determined: it conatains a GUG codon centered at position 26 that is not in phase with any termination codon within the 5' end nucleotide sequence of the RNA that we have analyzed (101 residues). However, the predicted N-terminal amino acid sequence starting from this GUG codon (or even from any AUG or GUG codon in the 5' end of the RNA) does not coincide with that of the in vitro-synthesized product of the 5' end proximal gag gene. Nevertheless, inhibition of ribosome binding to this site is accompanied by an inhibition of the in vitro translation of the gag gene.     

Thr region between the operator and first structural gene of the tryptophan operon of Escherichia coli may have a regulatory function

Among a collection of 34 independent mutants with internal deletions in the trp operon of Escherichia coli we found six that fail to recombine with any known point mutant in trpE, the first gene in the operon. These six deletion mutants are regulated normally by tryptophan and thus appear to have the trp operator region intact. However, four of these deletions result in alterations in the maximum level of expression of the trpC, B and A genes when compared with wild type or with an internal deletion of similar length which retains a small operatorproximal segment of trpE. Two of these deletion mutants, trpΔED1 and trpΔED12, have lower levels of the protein products of trpB and trpA than the control strains. In contrast, deletions trpΔED2 and trpΔED102 both markedly increase the levels of the trpB and trpA polypeptides. Deletion mutant trpΔED2 has 3 to 3.5 times and mutant trpΔED102 has seven to eight times as much tryptophan synthetase β₂ and α proteins as the wild-type or deletion control strains. The increase in tryptophan synthetase β₂ and α proteins seen is a consequence of an increase in the level of trp mRNA directing the synthesis of these enzymes. The rate of synthesis of trpBA mRNA is increased in trpΔAED2 about twofold, and in trpΔED102 about four- to sixfold over the control strain. The left-hand deletion end-points of both trpΔED2 and trpΔAED102 have been shown to map to the right of a known trp operator-constitutive mutation and appear to lie before the first translation start codon in trpE (M. Bronson, C. Squires &; C. Yanofsky, unpublished results). We propose that these deletions alter a region between the earliest known trpE point mutation and the trp operator which influences the maximum rate of synthesis of trp operon mRNA.     

The Seryl-tRNA synthetase/tRNA acceptor stem interface is mediated via a specific network of water molecules

tRNAs are aminoacylated by the aminoacyl-tRNA synthetases. There are at least 20 natural amino acids, but due to the redundancy of the genetic code, 64 codons on the mRNA. Therefore, there exist tRNA isoacceptors that are aminoacylated with the same amino acid, but differ in their sequence and in the anticodon. tRNA identity elements, which are sequence or structure motifs, assure the amino acid specificity. The Seryl-tRNA synthetase is an enzyme that depends on rather few and simple identity elements in tRNA^Ser. The Seryl-tRNA-synthetase interacts with the tRNA^Ser acceptor stem, which makes this part of the tRNA a valuable structural element for investigating motifs of the protein–RNA complex. We solved the high resolution crystal structures of two tRNA^Ser acceptor stem microhelices and investigated their interaction with the Seryl-tRNA-synthetase by superposition experiments. The results presented here show that the amino acid side chains Ser151 and Ser156 of the synthetase are interacting in a very similar way with the RNA backbone of the microhelix and that the involved water molecules have almost identical positions within the tRNA/synthetase interface.     

The Drosophila homologue of the 64 kDa subunit of cleavage stimulation factor interacts with the 77 kDa subunit encoded by the suppressor of forked gene

During mRNA 3′ end formation, cleavage stimulation factor (CstF) binds to a GU-rich sequence downstream from the polyadenylation site and helps to stabilise the binding of cleavage-polyadenylation specificity factor (CPSF) to the upstream polyadenylation sequence (AAUAAA). The 64 kDa subunit of CstF (CstF-64) contains an RNA binding domain and is responsible for the RNA binding activity of CstF. It interacts with CstF-77, which in turn interacts with CPSF. The Drosophila suppressor of forked gene encodes a homologue of CstF-77, and mutations in it affect mRNA 3′ end formation in vivo. A Drosophila homologue for CstF-64 has now been isolated, both through homology with the human protein and through protein–protein interaction in yeast with the suppressor of forked gene product. Alignment of CstF-64 homologues shows that the proteins have a conserved N-terminal 200 amino acids, the first half of which is the RNA binding domain with the second half likely to contain the CstF-77 interaction domain; a central region variable in length and rich in glycine, proline and glutamine residues and containing an unusual degenerate repeat motif; and then a conserved C-terminal 50 amino acids. In Drosophila, the CstF-64 gene has a single 63 bp intron, is transcribed throughout development and probably corresponds to l(3)91Cd.